KR19980026544A - Coil winding of deflection yoke - Google Patents

Abstract

According to the present invention, the winding density of the deflection yoke coil is distributed on the curved surface of the coil, and the guide surface 12 is formed on the side wall 14 of the guide surface 12 formed on one side of the winding surface 11 of the winding 10. And a plurality of pin holes 16 horizontally penetrated from the side wall 14 of the side to the winding surface with different heights, and the air cylinder 15 at the position corresponding to each of the pin holes 16. It is installed in the inner space portion 13 of the side wall 14 of the 12, and engages the operation pin 17, which is slidingly coupled to the pin hole 16 to the air cylinder 15, the operation pin 17 is wound By supporting the corner angle of the coil 20 wound on the winding surface 11 of 10, the winding density of the coil 20 wound on the winding surface 11 of the winding 10 is distributed to It is to improve the magnetic field effect of the coil 20 forming one part.

Description

Coil winding of deflection yoke

The deflection yoke coil generates a magnetic force by the current supplied to the deflection yoke and serves to deflect the electron beam emitted from the electron gun.

The mold installed in the winding machine for automatically winding the deflection yoke coil is a winding type, and the winding type includes a winding surface having the same curved surface as the shape of the coil in which the winding is completed and a guide surface in which the coil is wound and guided. The shape and structure are directly related to the winding accuracy of the coil.

The shape of the coil is generally saddle-shaped, and the coil has an inclination along the length of the coil, and the curvature of the curved surface also changes according to the inclination.

In order to improve the magnetic field effect, the deflection yoke coil should be wound so that the coil is distributed on the curved surface of the coil as a whole.

Fig. 1 shows a conventional wound structure, and Fig. 2 is a perspective view showing the shape of a deflection yoke coil wound by the conventional wound structure.

The conventional winding 10 illustrated in FIG. 1 forms a winding surface 11 corresponding to a completed shape of the winding of the coil 20 at the center thereof, and the winding surface 11 forms a slope in a curved surface, and a curved surface. The curvature varies depending on the change in the slope of the.

Guide surfaces 12 are formed at the left and right sides of the winding surface 11 of the winding 10, and the guide surfaces 12 at the left and right sides are formed in curved surfaces, respectively, and the inside of the winding 10 has a weight of the winding 10. Form the space 13 to reduce.

In this conventional winding 10, when the winding 10 is installed in the winding machine and the winding machine is operated, the winding 10 is rotated together with the operation of the winding machine, and the coil wound on the bobbin is introduced into the winding machine while being unwinded. The coils introduced into the winding machine are sequentially wound on the winding surface 11 of the winding 10 which is rotated while flowing along the guide surface 12 of the winding 10.

As can be seen from the shape of the coil 20 illustrated in FIG. 1, the coil 20 has a saddle shape formed in a curved shape with an inclination in the longitudinal direction. The winding order of the coil 20 is wound from the inside of the coil 20 to the outside.

In the conventional winding structure, the winding shape of the coil 20 is wound with a constant thickness along the outline rim of the coil 20, and the coil 20 may be formed at the center of the coil 20 at a position where the curved bone curvature of the coil 20 is large. Since the area of the empty space in which the coil 20 is not wound is increased, there is a problem of lowering the efficiency of the magnetic field effect of the coil 20 according to the number of turns of the coil 20.

Therefore, the present invention has been made to solve the above problems, the object is to distribute the winding density of the deflection yoke coil to the curved surface of the coil, to improve the magnetic field generation effect of the coil to improve the electron beam deflection of the deflection yoke To provide a deflection yoke coil winding.

1 is a front view showing a conventional winding structure

2 is a perspective view of a coil wound by the winding of FIG.

3 is a front sectional view showing the winding of the present invention.

4 is a cross-sectional view of the A-A portion of FIG.

5 is a perspective view of a coil wound by the present invention, FIG. 3

* Description of the symbols for the main parts of the drawings *

10: winding 11: winding surface

12: guide surface 13: space part

14 side wall 15 air cylinder

16: pin hole 17: working pin

20: coil

In order to achieve the above object, the present invention provides a plurality of pin holes horizontally penetrated from the side wall of the guide surface to the winding surface on the side wall of the guide surface formed on one side of the winding surface of the winding, the respective pin holes The air cylinder is installed at a position corresponding to the inner space of the side wall of the guide surface, and the operation pin coupled to the air cylinder slidingly coupled to the pin hole is a basic feature of the technical configuration.

An embodiment of the present invention configured as described above will be described in detail with reference to the accompanying drawings.

Figure 3 shows the winding structure of the present invention, Figure 4 is a perspective view showing the coil shape wound by the winding of the present invention.

As shown in FIG. 3, the winding 10 of the present invention forms a winding surface 11 corresponding to the winding shape of the coil in the center portion, and a guide surface (left and right sides) of the winding surface of the winding 10. 12, and the inside of the guide surface 12 of the winding 10 forms a space portion (13). A pin hole 16 horizontally penetrated from the side wall 14 of the guide surface 12 to the winding surface 11 on the side wall 14 of the guide surface 12, which is a boundary between the winding surface 11 and the guide surface 12. ) Many awards. It is formed in several layers.

The air cylinder 15 is installed in the inner space 13 of the side wall 14 of the guide surface 12 at a position corresponding to each of the pin holes 16.

The operation pin 17 slidingly coupled to the pin hole 16 is configured to be coupled to the air cylinder 15.

Referring to the operation and effects of the present invention as follows.

In the winding 10 of the present invention, the actuating pin 17 is horizontally translated in the winding plane direction through the pin hole 16 by the air cylinder 15, and the reciprocating stroke of the air cylinder 15 is a guide plane. The operation order differs depending on the upper and lower layers of the air cylinder 15 provided on the side wall of (12).

When the coil 20 is wound on the winding surface 11 of the winding 10, when winding the inner side of the coil 20, the operation pin 17 of the uppermost layer protrudes due to the operation of the air cylinder 15, so that the coil ( The corner angle of 20) is taken. When a certain amount of coil 20 is wound from the inside to the outside on the inner side of the coil 20, the actuating pin 17 of the uppermost layer is inserted by the operation of the air cylinder 15, and the actuating pin 17 of the next layer is The corner angle of the coil 20 which protrudes on the winding surface 11 of the winding 10 in conjunction with the insertion of the operation pin 17 of the uppermost layer is taken, and the winding of the coil 20 is continued. When the winding amount of the coil 20 to be wound again becomes constant, the operation pin 17 of the next layer is inserted, the operation pin 17 below the operation pin 17 of the next layer is protruded, and the coil 20 It is wound from the inside to the outside to terminate the winding of the coil 20.

The winding density of the coil 20 in which the winding of the coil 20 is completed in the winding machine by the winding 10 is inversely proportional to the curvature of the curved surface according to the longitudinal slope of the coil 20. That is, the coil 20 is densely wound in the place where the curved curvature of the coil 20 is small, and the winding density of the coil 20 becomes small in the portion where the curved curvature of the coil 20 is large. Therefore, the winding density of the coil 20 is wound so that the coil 20 is distributed along the curved surface at the position where the curved curvature of the coil 20 is large.

As described above, the present invention provides a winding density distribution of a coil wound on a winding surface of a winding by installing an actuating pin on a winding for holding a winding shape of a coil to be translationally operated by an air cylinder to one side of the guide surface wall of the winding. As a result, the magnetic field effect of the coil forming a part of the deflection yoke is improved to improve the quality of the deflection yoke.

The present invention relates to a structure of a winding used when winding a coil of a deflection yoke, and in particular, an actuating pin for catching a change in the corner angle of a coil during winding of a deflection yoke coil is installed on the winding to be operated by a fluid mechanism. The present invention relates to a deflection yoke coil winding in which the winding density is distributed.

Claims (1)

In the deflection yoke coil winding in which a winding surface corresponding to the winding shape of the coil is formed in the center portion and a guide surface is formed on the left and right sides of the winding surface of the winding, A plurality of pin holes horizontally penetrated from the side wall of the guide surface to the winding surface of the guide surface formed on one side of the winding surface of the winding are formed with different vertical heights, and the air cylinder is positioned at a position corresponding to each of the pin holes. The deflection yoke coil winding is installed in the inner space portion of the side wall of the guide surface, and coupled to the air cylinder an operation pin slidingly coupled to the pin hole.